Method and apparatus for transmitting power headroom report by terminal in wireless communication system

ABSTRACT

Disclosed are a method and an apparatus for transmitting a power headroom report (PHR) by a terminal which is set to be dually connected to at least two heterogeneous base stations through uplink wireless connection. A method for transmitting a power headroom report (PHR) by a user equipment performing wireless communication based on dual connectivity. The method may include triggering the PHR based on at least one of a path loss change and a periodic timer; and transmitting at least one PHR to at least one base station according to the dual connectivity.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation of U.S. patent application Ser. No.14/782,468, filed on Oct. 5, 2015, now issued as U.S. Pat. No.9,961,648, which is a National Stage Entry of International PatentApplication No. PCT/KR2014/002542, filed on Mar. 26, 2014, and claimspriority from and the benefit of Korean Patent Application No.10-2013-0037322 filed on Apr. 5, 2013, each of which is herebyincorporated by reference for all purposes as if fully set forth herein.

BACKGROUND Field

Exemplary embodiments relate to wireless communication, and moreparticularly, to a method and an apparatus for transmitting powerheadroom by a user equipment dually connected to a plurality ofheterogeneous base stations.

Discussion of the Background

A base station can use power headroom information of a user equipment inorder to efficiently use resources of the user equipment. A powercontrol technology is an essential core technology for minimizinginterference elements and reducing consumption of a battery of the userequipment in order to efficiently distribute the resources in wirelesscommunication.

When the user equipment provides the power headroom information to thebase station, the base station can estimate maximum uplink transmissionpower which the user equipment can cope with. Accordingly, the basestation can provide uplink scheduling such as transmission powercontrol, modulation and coding levels, and a bandwidth to the userequipment within a range not to departing from a limit of the estimatedmaximum uplink transmission power.

Meanwhile, the user equipment can receive services through differentfrequency bands from a small base station including a small cell and amacro base station including a macro cell. This is also referred to as adual connection.

A method in which the dually connected user equipment performs efficientuplink resource allocation during reporting power headroom is required.

SUMMARY

Exemplary embodiments provide a method and an apparatus for transmittinga power headroom report.

Exemplary embodiments also provide a method and an apparatus fortransmitting a power headroom report based on a connection configurationof a user equipment.

Exemplary embodiments also provide a method and an apparatus fortransmitting a power headroom report by a user equipment duallyconnected to a small base station and a macro base station.

Exemplary embodiments also provide a method and an apparatus fortransmitting a power headroom report according to a downlink or uplinkconnection of the user equipment.

In an aspect, a method for transmitting a power headroom report by auser equipment of which uplink radio connection with two or moredifferent base stations is configured as dual connectivity, includes:triggering the PHR based on a path loss change and a periodic timer; andtransmitting at least one PHR to at least one base station according tothe dual connectivity; transmitting a PHR including both first powerheadroom (PH) for a first frequency band which is a serving frequency ofthe first base station and second PH for a second frequency band whichis the serving frequency of the second base station to the first basestation or the second base station when the user equipment is capable ofsimultaneously receiving downlink signals from the first base stationand the second base station and simultaneously transmitting an uplinksignal; transmitting a PHR including the first PH to the first basestation and a PHR including the second PH to the second base stationwhen uplink radio connection of the user equipment with the first basestation and the second base station is configured, and the userequipment is capable of simultaneously receiving the downlink signalsbut transmitting the uplink signal to only one base station at a time;and storing the PHR for the first frequency band in the user equipmentand transmitting the PHR for the first frequency band to the second basestation in the case where a PHR for the second base station is triggeredwhen the user equipment is capable of receiving the downlink signal fromone base station of the first base station and the second base stationat a time and transmitting the uplink signal to only the base station ata time corresponding thereto.

According exemplary embodiments, under a situation in which dualconnectivity between a macro cell and a small cell, and a user equipmentis configured on a network, a power headroom report can be efficientlytransferred and uplink resource allocation can be more efficientlyperformed based thereon.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a wireless communication system according to anexemplary embodiment.

FIG. 2 illustrates one example of a dual connectivity situation of UEaccording to an exemplary embodiment.

FIG. 3 is one example of a case in which UE is configured to be duallyconnected with a small base station and a macro base station.

FIG. 4 is another example of a case in which UE is configured to bedually connected with a small base station.

FIG. 5 is a flowchart illustrating one example of a procedure in whichUE reports power headroom according an exemplary embodiment.

FIG. 6 illustrates one example in which UE triggers a PHR based on achange in path loss value.

FIG. 7 is a diagram illustrating one example of a PLR configurationaccording to an exemplary embodiment.

FIG. 8 is a diagram illustrating one example of a configuration of a PHRprohibit timer.

FIG. 9 illustrates one example of an MAC control element of a PHR whichUE transmits to a first base station or a second base station accordingan exemplary embodiment.

FIG. 10 is a flowchart illustrating another example of a procedure inwhich UE reports power headroom according an exemplary embodiment.

FIG. 11 is a flowchart illustrating yet another example of a procedurein which UE reports power headroom according an exemplary embodiment.

FIG. 12 illustrates one example of an uplink frame structure including aPHR which UE transmits to a first base station or a second base stationaccording an exemplary embodiment.

FIG. 13 illustrates one example of a PHR MAC CE which UE transmits to abase station including a primary serving cell.

FIG. 14 illustrates one example of a PHR MAC CE which UE transmits to abase station not including a primary serving cell.

FIG. 15 is a flowchart illustrating still another example of a procedurein which UE reports power headroom according an exemplary embodiment.

FIG. 16 illustrates one example of an uplink frame structure including aPHR which UE transmits to a second base station according an exemplaryembodiment.

FIG. 17 illustrates yet another example of a PHR MAC CE which UEtransmits to a base station according to an exemplary embodiment.

FIG. 18 illustrates still another example of a PHR MAC CE which UEtransmits to a base station according to an exemplary embodiment.

FIG. 19 is a flowchart illustrating still yet another example of aprocedure in which UE reports power headroom according to an exemplaryembodiment.

FIG. 20 is a flowchart illustrating one example of an operation of UEwhich reports power headroom according to an exemplary embodiment.

FIG. 21 is one example of a flowchart illustrating an operation of abase station according to an exemplary embodiment. The base station maybe a small base station or a macro base station.

FIG. 22 is a block diagram illustrating an example of an apparatus oftransmitting and receiving power headroom reports according to anexemplary embodiment.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

The inventive concept will be described more fully hereinafter withreference to the accompanying drawings, in which exemplary embodimentsare shown. However, the inventive concept can be realized in variousdifferent forms, and is not limited to the embodiments described herein.Further, parts not related with the inventive concept are omitted indrawings for clearly describing the exemplary embodiments and likereference numerals which are the same or similar designate like elementsthe drawings.

FIG. 1 illustrates a wireless communication system according to anexemplary embodiment.

Referring to FIG. 1, the wireless communication system 10 is widelyplaced to provide various communication services such as a voice, packetdata, and the like. The wireless communication system 10 includes atleast one base station (BS) 11. Each base station 11 provides acommunication service to specific cells 15 a, 15 b, and 15 c. The cellmay be redivided into a plurality of areas (referred to as sectors).

A user equipment (UE) 12 may be fixed or movable and may be called otherterms such as a mobile station (MS), a mobile user equipment (MT), auser equipment (UT), a subscriber station (SS), a wireless device, apersonal digital assistant (PDA), a wireless modem, a handheld device,and the like. The base station 11 may be called other terms such as anevolved-NodeB (eNBb), a base transceiver system (BTS), an access point,a femto base station, a home nodeB, a relay, and the like. The cellneeds to be analyzed as a comprehensive meaning representing a partialarea covered by the base station and embraces all of various coverageareas including a mega cell, a macro cell, a small cell, a micro cell, apico cell, femto cell, and the like.

Hereinafter, the downlink means communication from the base station 11to the UE 12 and the uplink means communication from the UE 12 to thebase station 11. In the downlink, the transmitter may be a part of thebase station 11 and the receiver may be a part of the UE 12. In theuplink, the transmitter may be a part of the UE 12 and the receiver maybe a part of the base station 11.

The wireless communication system may adopt various multiple accesstechniques including code division multiple access (CDMA), time divisionmultiple access (TDMA), frequency division multiple access (FDMA),orthogonal frequency division multiple access (OFDMA), singlecarrier-FDMA (SC-FDMA), OFDM-FDMA, OFDM-TDMA, and OFDM-CDMA.

The time division duplex (TDD) scheme in which transmission is performedby different times or the frequency division duplex (FDD) scheme inwhich transmission is performed by using different frequencies may beused for the uplink transmission and the downlink transmission.

In a physical layer, physical control channels described below are used.A physical downlink control channel (PDCCH) notifies resource allocationof a paging channel (PCH) and a downlink shared channel (DL-SCH) andhybrid automatic repeat request (HARQ) information associated with theDL-SCH to the UE. The PDCCH may transport an uplink grant for notifyingresource allocation of uplink transmission to the UE. The DL-SCH ismapped to a physical downlink shared channel (PDSCH). A physical controlformat indicator channel (PCFICH) notifies the number of OFDM symbolsused in the PDCCHs to the UE and is transmitted every subframe. Aphysical Hybrid ARQ Indicator Channel (PHICH) as a downlink channeltransports an HARQ ACK/NACK signal which is a response to the uplinktransmission. A physical uplink control channel (PUCCH) transportsuplink control information such as an HARQ ACK/NACK signal, a schedulingrequest, and a CQI for downlink transmission. A physical uplink sharedchannel (PUSCH) transports an uplink shared channel (UL-SCH). A physicalrandom access channel (PRACH) transports a random access preamble.

A frame is constituted by 10 subframes. The subframe includes aplurality of OFDM symbols. A carrier may have a control channel (e.g.,PDCCH) thereof.

A component carrier may be divided into a primary component carrier(PCC) and a secondary component carrier (SCC). The UE may use only oneprimary component carrier or use one or more secondary componentcarriers in addition to the primary component carrier. The UE may beallocated with the primary component carrier and/or the secondarycomponent carrier from the base station.

A primary serving cell (alternatively, primary cell or PCell) means oneserving cell that provides a security input and non-access stratummobility information in an RRC connection establishment (alternatively,referred to as configuration) or re-establishment (alternatively,reconfiguration) state. According to capabilities of the user equipment,at least one cell may be configured to form a set of serving cellstogether with the primary serving cell and the at least one cell isreferred to as the second serving cell (alternatively, secondary cell orSCell).

Accordingly, a set of serving cells configured for one user equipmentmay be configured by only one primary serving cell or by one primaryserving cell and at least one secondary serving cell.

A downlink component carrier corresponding to the primary serving cellis referred to as a downlink primary component carrier (DL PCC) and anuplink component carrier corresponding to the primary serving cell isreferred to as an uplink primary component carrier (UL PCC). Further, inthe downlink, a component carrier corresponding to the secondary servingcell is referred to as a downlink secondary component carrier (DL SCC)and in the uplink, a component carrier corresponding to the secondaryserving cell is referred to as an uplink secondary component carrier (ULSCC). Only the downlink component carrier may correspond to one servingcell and both DL CC and the UL CC may correspond to one serving cell.

Accordingly, communication between the UE and the base station which isachieved through the DL CC or UL CC in a carrier system is a conceptequivalent to communication between the UE and the base station which isachieved through the serving cell. For example, in a random accessperforming method according to an exemplary embodiment, transmitting, bythe UE, the preamble by using the UL CC may be regarded as a conceptequivalent to transmitting the preamble by using the primary servingcell or the secondary serving cell. Further, receiving, by the UE,downlink information by using the DL CC may be regarded as a conceptequivalent to receiving the downlink information buy using the primaryserving cell or the secondary serving cell.

Meanwhile, the primary serving cell and the secondary serving cell havethe following features.

First, the primary serving cell is used for transmission of the PUCCH.On the contrary, the secondary serving cell may not transmit the PUCCH,but transmit some control information among information in the PUCCHthrough the PUSCH.

Second, the primary serving cell is continuously activated, while thesecondary serving cell is a carrier activated/deactivated according to aspecific condition. The specific condition may become a case in which anactivation/deactivation indicator of the base station is received or adeactivated timer in the UE expires. The activation represents thattraffic data is transmitted or received or is in a ready state. Thedeactivation represents that the traffic data cannot be transmitted orreceived, or measurement or minimum information can betransmitted/received.

Third, in the primary serving cell, the DL PCC and the UL PCC areconstituted as a pair.

Fourth, different CCs may be configured as the primary serving cells inrespective user equipments.

Fifth, the PUCCH configured in the primary serving cell may be definedwith respect to the special secondary serving cell. Alternatively, acontention based random access procedure may be defined with respect tothe special secondary serving cell. The PUCCH may be defined withrespect to a specific secondary serving cell later, and as a result, atype of a PUCCH including type 1 power headroom information and type 2power headroom information for the special secondary serving cell areincluded may be considered.

Sixth, the PUCCH for the special secondary serving cell may be fixedlyconfigured at the time of configuring the special secondary serving cellor allocated (configured) or cancelled by RRC signaling (RRCreconfiguration message) when the base station reconfigures the PUCCHfor the corresponding secondary serving cell.

The PUCCH for the special secondary serving cell may include ACK/NACKinformation or channel quality information (CQI) of secondary servingcells which exist in a specific group which the base station configuresby using the RRC signaling. Herein, the specific group may be asecondary timing alignment group (sTAG) or a group constituted byserving cells included in a specific base station (e.g., a macro basestation including only macro cells or a small base station includingonly small cells).

Seventh, the base station may configure one special secondary servingcell among multiple secondary serving cells in the specific group or notconfigure the special secondary serving cell. The reason why the basestation does not configure the special secondary serving cell is that itis determined that the contention based random access procedure or thePUCCH need not be configured for the specific group. As one example,such a case is a case in which it is determined that the contentionbased random access procedure need not be performed even in anysecondary serving cell in the specific group or it is determined that acapacity of the PUCCH of the current primary serving cell is sufficient,and as a result, a PUCCH for an additional secondary serving cell neednot be configured.

The technical spirit regarding the features of the primary serving celland the secondary serving cell is not particularly limited to the abovedescription and this is just an example and may include more examples.

In a wireless communication environment, a propagation delay may occurwhile a transmitter propagates a radio wave and a receiver transfers theradio wave. Accordingly, even tough both the transmitter and receiveraccurately know the time when the transmitter propagates the radio wave,a time when a signal reaches the receiver is influenced by a distancebetween the transmitter and the receiver, a surrounding propagationenvironment, and the like and when the receiver moves, the time variesaccording to the time. When the receivers may not accurately know thetime of receiving the signal transferred by the transmitter, a failurein receiving the signal is made or a distorted signal is received inspite of receiving the signal, and as a result, communication becomesinvalid.

Accordingly, in a wireless communication system, synchronization betweenthe base station and the UE needs to be particularly decided first inorder to receive an information signal regardless of downlink ordownlink. The type of the synchronization includes various typesincluding frame synchronization, information symbol synchronization,sampling period synchronization, and the like. Herein, the samplingperiod synchronization is synchronization which needs to be mostbasically acquired in order to distinguish a physical signal.

In the case of the uplink, the base station receives signals transmittedfrom multiple UEs. When distances between the respective UEs and thebase station are different from each other, signals received by therespective base stations have different transmission delay times andwhen uplink information is transmitted based on downlink synchronizationacquired by each UE, the corresponding base station receives informationof each UE at different times. In this case, the base station may notacquire synchronization based on any one UE. Accordingly, acquisition ofuplink synchronization requires a procedure a different procedure fromacquisition of the downlink synchronization.

A random access procedure is performed to acquire the uplinksynchronization of the UE and during the random access procedure, the UEacquires the uplink synchronization based on a timing alignment value(alternatively, referred to as a TA value) transmitted from the basestation. In terms of advancing an uplink time, the timing alignmentvalue may also be called a timing advanced value.

Meanwhile, in a multiple-carrier system, one UE performs communicationwith the base station through a plurality of component carriers or aplurality of serving cells. When all signals of the plurality of servingcells configured in the UE have the same time delay, the UE may acquirethe uplink synchronization for all serving cells only by one timingalignment value. On the contrary, when the signals of the plurality ofserving cells have different time delays, different timing alignmentvalues are required for the respective serving cells. That is, multipletiming alignment values are required. When the UE performs the randomaccess one by one for each serving cell in order to acquire the multipletiming alignment values, overhead may occur in limited uplink resourcesand complexity of the random access may increase. A timing alignmentgroup (TAG) is defined in order to reduce the overhead and thecomplexity.

The timing alignment group may include the primary serving cell and thetiming alignment group may include at least one secondary serving cell.

Hereinafter, power headroom (PH) will be described.

The power headroom means spare power which may be additionally used inaddition to power which the UE currently uses for uplink transmission.For example, it is assumed that maximum transmission power which isuplink transmission power in an allowable range of the UE is 10 W and itis assumed that the UE currently uses power of 9 W in a frequency bandof 10 MHz. In this case, since the UE may additionally use 1 W, thepower headroom becomes 1 W.

Herein, when the base station allocates a frequency band of 20 MHz tothe UE, power of 18 W (=9 W×2) is required. However, since maximum powerof the UE is 10 W, when 20 MHz is allocated to the UE, the UE may notuse the entirety of the frequency band or the power is insufficient, andas a result, the base station may not normally receive the signal of theUE. In order to solve the problem, the UE reports that the powerheadroom is 1 W to the base station to allow the base station to performscheduling within a power headroom range. Such a report is referred toas a power headroom report (PHR).

Through a power headroom reporting procedure, 1) information on adifference between maximum transmission power of the UE which is nominalfor each activated serving cell and estimated UL-SCH (PUSCH)transmission power, 2) information on a difference between maximumtransmission power of the UE which is nominal in the primary servingcell and estimated PUCCH transmission power, or 3) information on adifference between the maximum transmission power of the UE which isnominal in the primary serving cell and the estimated UL-SCH and PUCCHtransmission power may be transmitted to the serving base station.

The power headroom report may be defined as two types (type 1 and type2). Power headroom of a predetermined UE may be defined with respect tosubframe i for serving cell c.

<1. Power Headroom Report Type 1 (Type 1 Power Headroom)>

In regard to the type 1 power headroom, there are cases where the UE 1)transmits only the PUSCH without the PUCCH, 2) transmits both the PUCCHand the PUSCH, and 3) does not transmit the PUSCH.

First, in the case where the UE transmits the PUSCH without the PUCCHwith respect to subframe i for serving cell c, power headroom for a type1 report is shown in an equation given below.PH_(type1,c)(i)=P _(CMAX,c)(i)−{10 log₁₀(M _(PUSCH,c)(i))+P _(O) _(_)_(PUSCH,c)(j)+α_(c)(j)·PL_(c)+Δ_(TF,c)(i)+f _(c)(i)}[dB]  [Equation 1]

Where, P_(CMAX,c)(i) is a value acquired by converting maximum UEtransmission power, {circumflex over (P)}_(CMAX,c)(i) configured withrespect to serving cell c into a decibel value [dB].

Where, P_(CMAX)(i) is a maximum UE transmission power value calculatedby applying offset values set on a network based on a maximumtransmission power value set based on the smaller value of a P_(EMAX)value set based on P-max as a value which the base station transmits tothe UE through the RRC signaling and a P_(PowerClass) value determinedby a transmission power class determined by the level of hardware ofeach UE. Herein, the offset values may be a maximum power reduction(MPR) value, an additional maximum power reduction (A-MPR) value, and apower management maximum power reduction (P-MPR) value and additionallyadopt an offset value ΔT_(C) adopted according to a band having a lot offilter characteristics in a transmitting unit of the UE or not.

The P_(CMAX,c)(i) is a value configured only for serving cell c unlikeP_(CMAX)(i). Therefore, the P-max value is also a value P_(EMAX,c)configured with respect to serving cell c and each of the offset valuesare also calculated as a value configured only for serving cell c. Thatis, the offset values are constituted by MPR_(c), A-MPR_(c), P-MPR_(c),and ΔT_(C,c). However, the P_(PowerClass) value is calculated by using avalue which is the same as a value used in calculation by the unit ofthe UE.

Further, M_(PUSCH,c)(i) is a value acquired by expressing a bandwidth ofa resource which the PUSCH is allocated in subframe i for serving cell cas the number of RBs.

In addition, P_(O) _(_) _(PUSCH,c)(j) represents the sum of P_(O) _(_)_(NOMINAL) _(_) _(PUSCH,c)(j) and P_(O) _(_) _(UE) _(_) _(PUSCH,c)(j)for serving cell c and j is 0 or 1 from a higher layer. In the case ofsemi-persistent grant PUSCH transmission (alternatively,retransmission), j is 0, while in the case of dynamic scheduled grantPUSCH transmission (alternatively, retransmission), j is 1 and in thecase of random access response grant PUSCH transmission (alternatively,retransmission), j is 2. Further, in the case of the random accessresponse grant PUSCH transmission (alternatively, retransmission), P_(O)_(_) _(UE) _(_) _(PUSCH,c)(2)=0 and P_(O) _(_) _(NOMINAL) _(_)_(PUSCH,c)(2) represents the sum of P_(O) _(_) _(PRE) and _(PREAMBLE)_(_) _(Msg3), where parameters P_(O) _(_)_(PRE)(preambleInitialReceivedTargetPower) and Δ_(PREAMBLE) _(_) _(Msg3)are signaled from the higher layer.

When j is 0 or 1, one of α_(c)∈{0, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1}values may be selected by a 3-bit parameter provided from the higherlayer. When j is 2, α_(c)(j)=1 at all times.

PL_(c) represents a Db value of a prediction value of downlink path loss(also referred to as PL or path attenuation or path decrement) forserving cell c calculated in the UE and may be acquired from“referenceSignalPower-higher layer filtered RSRP”. Herein,referenceSignalPower as a value provided from the higher layerrepresents a dBm unit of an energy per resource element (EPRE) value ofa downlink reference signal. Reference signal received power (RSRP)represents a received power value of the reference signal for areference serving cell. The serving cell selected as the referenceserving cell and determination of referenceSignalPower and higher layerfiltered RSRP used for calculating the PL_(c) is configured byathlossReferenceLinking which is a higher layer parameter. Herein, thereference serving cell configured by pathlossReferenceLinking may be aDL SCC of a secondary serving cell SIB2-connected with (correspondingto) the primary serving cell or the UL CC.

Further, Δ_(TF,c)(i) represents a parameter for reflecting an influenceby a modulation coding scheme (MCS) and a value of Δ_(TF,c)(i) is 10log₁₀((2^(BPRE·K) ^(S) −1)·β_(offset) ^(PUSCH)). Where, K_(s) representsa parameter provided as deltaMCS-Enabled from the higher layer withrespect to each serving cell c and is 1.25 or 0 and in particular, inthe case of transmission mode 2 which is a mode for transmit diversity,K_(s) is 0 at all times. Further, in the case where only controlinformation is transmitted through the PUSCH without the UL-SCH,BPRE=O_(CQI)/N_(RE) and in other cases,

${{BPRE} = {\sum\limits_{r = 0}^{C - 1}\frac{K_{r}}{N_{RE}}}},$where, C represents the number of code blocks, K_(r) represents the sizeof the code block, O_(CQI) represents the number of CQI/PMI bitsincluding a CRC bit number, and N_(RE) represents the number ofdetermined resource elements (that is, N_(RE)=M_(SC)^(PUSCH-initial)·N_(symb) ^(PUSCH-initial)). Further, in the case whereonly the control information is transmitted through the PUSCH withoutthe UL-SCH data, β_(offset) ^(PUSCH)=β_(offset) ^(CQI) is configured andin other cases, β^(PUSCH) _(offset) is set to 1 at all times.

In addition, δ_(PUSCH,c) a correction value is determined by referringto a TPC command that exists in DCI format 0 or DCI format 4 for servingcell c or a TPC command in DCI format 3/3A encoded and transmittedcommonly with other UEs. The DCI format 3/3A may be verified by only UEsto which the RNTI value is allocated because CRC parity bits arescrambled to TPC-PUSCH-RNTI. Herein, in the case of the RNTI value, whena predetermined UE is constituted by multiple serving cells, differentRNTI values may be allocated for each serving cell in order todistinguish each serving cell. In this case, a PUSCH power controladjustment state for current serving cell c is given as f_(c)(i) andwhen accumulation is activated by the higher layer with respect toserving cell c or when DCI format 0 in which the TPC command,δ_(PUSCH,c) is scrambled by temporary-C-RNTI is included in the PDCCH,“f_(c)(i)=f_(c)(i−1)+δ_(PUSCH,c)(i−K_(PUSCH))”. Where,δ_(PUSCH,c)(i−K_(PUSCH)) represents a TPC command which exists in DCIformat 0/4 or 3/3A in the PDCCH transmitted in an (i−K_(PUSCH))-thsubframe and f_(c)(0) represents a first value after accumulation isreset. Further, a value of K_(PUSCH) is 4 in the case of FDD. In thecase where the PDCCH that schedules PUSCH transmission in subframe 2 or7 when TDD UL/DL is set 0, if a least significant bit (LSB) value of aUL index in DCI format 0/4 in the PDCCH is set to 1, K_(PUSCH) is 7.

Second, in the case where the UE transmits both the PUCCH and the PUSCHwith respect to subframe i for serving cell c, the type 1 power headroomis shown in an equation given below.PH_(type1,c)(i)={tilde over (P)} _(CMAX,c)(i)−{10 log₁₀(M_(PUSCH,c)(i))+P _(O) _(_) _(PUSCH,c)(j)+α_(c)(j)·PL_(c)+Δ_(TF,c)(i)+f_(c)(i)}[dB]  [Equation 2]

Where, {tilde over (P)}_(CMAX,c)(i) is a value calculated on theassumption that only the PUSCH is transmitted in subframe i. In thiscase, the physical layer transfers {tilde over (P)}_(CMAX,c)(i) to thehigher layer instead of P_(CMAX,c)(i).

Third, in the case where the UE does not transmit the PUSCH with respectto subframe i for serving cell c, the type 1 power headroom is shown inan equation given below.PH_(type1,c)(i)={tilde over (P)} _(CMAX,c)(i)−{P _(O) _(_)_(PUSCH,c)(1)+α_(c)(1)·PL_(c) +f _(c)(i)}[dB]  [Equation 3]

Where, {tilde over (P)}_(CMAX,c)(i) is calculated on the assumption thatMPR is 0 dB, A-MPR is 0 dB, P-MPR is 0 dB, and ΔT_(C) is 0 dB.

<2. Power Headroom Report Type 2 (Type 2 Power Headroom)>

In regard to the type 2 power headroom, there are a case where the UEtransmits both the PUCCH and the PUSCH with respect to subframe i forthe primary serving cell, a case where the UE transmits the PUSCHwithout the PUCCH, a case where the UE transmits the PUCCH without thePUSCH, and a case where the UE does not transmit the PUCCH or the PUSCH.

First, in the case where the UE transmits both the PUCCH and the PUSCHwith respect to subframe i for the primary serving cell, the type 2power headroom is shown in an equation given below.

                                     [Equation  4]PH_(type 2)(i) = P_(CMAX, c)(i) − 10 log₁₀  (10^((10l o g₁₀(M_(PUSCH, c)(i)) + P_(O_PUSCH, c)(j) + α_(c)(j) ⋅ PL_(c) + Δ_(TF, c)(i) + f_(c)(i))/10) + 10^((P_(O_PUCCH) + PL_(c) + h(n_(CQI), n_(HARQ), n_(SR)) + Δ_(F_PUCCH)(F) + Δ_(TxD)(F^(′)) + g(i))/10)  )  [dB]

Where, Δ_(F) _(_) _(PUCCH)(F) is defined in the higher layer (RRC) andeach Δ_(F) _(_) _(PUCCH)(F) value coincides with PUCCH format (F)associated with PUCCH format 1a. Herein, each PUCCH format (F) is shownin a table given below.

TABLE 1 PUCCH format Modulation scheme Bit number per subframe, M_(bit)1 N/A N/A 1a BPSK 1 1b QPSK 2 2 QPSK 20 2a QPSK + BPSK 21 2b QPSK + BPSK22 3 QPSK 48

When the UE is configured to transmit the PUCCH with respect to twoantenna ports by the higher layer, a value of Δ_(TxD)(F′) for each PUCCHformat F′ is received from the higher layer. Otherwise, Δ_(TxD)(F′)=0 atall times.

Further, h(n_(CQI),n_(HARQ),n_(SR)) has different values for each PUCCHformat. Where, n_(CQI) represents the bit number of the channel qualityinformation (CQI). Further, in the case where a scheduling request (SR)is configured in subframe i and the SR is not configured in apredetermined transmission block associated with the UL-SCH of the UE,n_(SR)=1 and in other cases, n_(SR)=0. When the UE is configured in oneserving cell, n_(HARQ) represents the HARQ-ACK bit number transmitted insubframe i. For PUCCH format 1/1a/1b, h(n_(CQI),n_(HARQ),n_(SR))=0. Inthe case where the UE is configured in one or more serving cells forPUCCH format 1b of channel selection,h(n_(CQI),n_(HARQ),n_(SR))=(n_(HARQ)−1)/2 and in other cases,h(n_(CQI),n_(HARQ),n_(SR))=0. For PUCCH format 2/2a/2b and a normalcyclic prefix, in the case where n_(CQI) is equal to or larger than 4,h(n_(CQI),n_(HARQ),n_(SR))=10 log₁₀(n_(CQI)/4) and in other cases,h(n_(CQI),n_(HARQ),n_(SR))=0. For PUCCH format 2 and an extended cyclicprefix, in the case where “n_(CQI)+n_(HARQ)” is equal to or larger than4, h(n_(CQI),n_(HARQ),n_(SR))=10 log₁₀((n_(CQI)+n_(HARQ))/4) and inother cases, h(n_(CQI),n_(HARQ),n_(SR))=0. For PUCCH format 3, in thecase where the UE is configured to transmit the PUCCH at two antennaports by the higher layer or the UE is configured to transmit theHARQ-ACK/SR of 11 bits, h(n_(CQI),n_(HARQ),n_(SR))=(n_(HARQ)+n_(SR)−1)/3and in other cases, h(n_(CQI),n_(HARQ),n_(SR))=(n_(HARQ)+n_(SR)−1)/2.P_(O) _(_) _(PUCCH) represents a parameter configured by the sum ofparameters P_(O) _(_) _(NOMINAL) _(_) _(PUCCH) and P_(O) _(_) _(UE) _(_)_(PUCCH) provided by the upper layer.

Second, in the case where the UE transmits the PUSCH without the PUCCHwith respect to subframe i for the primary serving cell, the type 2power headroom is calculated in an equation given below.

                                     [Equation  5]PH_(type 2)(i) = P_(CMAX, c)(i) − 10 log₁₀  (10^((10l og₁₀(M_(PUSCH, c)(i)) + P_(O_PUSCH, c)(j) + α_(c)(j) ⋅ PL_(c) + Δ_(TF, c)(i) + f_(c)(i))/10) + 10^((P_(O_PUCCH) + PL_(c) + g(i))/10))  [dB]

Third, in the case where the UE transmits the PUCCH without the PUSCHwith respect to subframe i for the primary serving cell, the type 2power headroom is calculated in an equation given below.

                                     [Equation  6]PH_(type 2)(i) =   P_(CMAX, c)(i) −     10 log₁₀(10^((P_(O_PUSCH, c)(j) + α_(c)(j) ⋅ PL_(c) + f_(c)(i))/10) +   10^((P_(O_PUCCH) + PL_(c) + h(n_(CQI), n_(HARQ), n_(SR)) + Δ_(F_PUCCH)(F) + Δ_(T × D)(F^(′)) + g(i))/10)) [dB]

Fourth, in the case where the UE does not transmit the PUCCH or thePUSCH with respect to subframe i for the primary serving cell, the type2 power headroom is calculated in an equation given below.

                                     [Equation  7]PH_(type 2)(i) = P_(CMAX, c)(i) −   10 log₁₀(10^((P_(O_PUSCH, c)(j) + α_(c)(j) ⋅ PL_(c) + f_(c )(i))/10) + 10^((P_(O_PUCCH) + PL_(c) + g(i))/10))  [dB]

Where, {tilde over (P)}_(CMAX,c)(i) is calculated on the assumption thatMPR is 0 dB, A-MPR is 0 dB, P-MPR is 0 dB, and ΔT_(C) is 0 dB.

The power headroom value is determined by the unit of 1 dB and needs tobe determined as a value which is nearest among values in the range of40 dB to −23 dB through round-off. The determined power headroom valueis transferred from the physical layer to the higher layer.

Meanwhile, the reported power headroom is a value estimated in onesubframe.

When an extended power headroom report (hereinafter, referred to asextended PHR) is not configured, only the type 1 power headroom valuefor the primary serving cell is reported. On the contrary, when theextended PHR is configured, the type 1 power headroom value and the type2 power headroom value are reported to respective activated servingcells in which the uplink is configured. The extended PHR will bedescribed below in detail.

A power headroom reporting delay represents a difference between a startpoint of time of a power headroom reference interval and a point of timewhen the UE starts transmitting the power headroom value through a radiointerface. The power headroom reporting delay needs to be 0 ms and thepower headroom reporting delay may be applied to all configuredtriggering techniques for reporting the power headroom.

Mapping of the reported power headroom may be given as shown in a tablegiven below.

TABLE 2 Reported value Measured quantity value (dB) POWER_HEADROOM_0 −23≤ PH <−22 POWER_HEADROOM_1 −22 ≤ PH <−21 POWER_HEADROOM_2 −21 ≤ PH <−20POWER_HEADROOM_3 −20 ≤ PH <−19 POWER_HEADROOM_4 −19 ≤ PH <−18POWER_HEADROOM_5 −18 ≤ PH <−17 . . . . . . POWER_HEADROOM_57 34 ≤ PH <35POWER_HEADROOM_58 35 ≤ PH <36 POWER_HEADROOM_59 36 ≤ PH <37POWER_HEADROOM_60 37 ≤ PH <38 POWER_HEADROOM_61 38 ≤ PH <39POWER_HEADROOM_62 39 ≤ PH <40 POWER_HEADROOM_63 PH = 40

Referring to Table 2, the power headroom belongs to the range of −23 dBto +40 dB. When 6 bits are used to express the power headroom, 64 (=2⁶)indexes may be shown, and as a result, the power headroom is dividedinto a total of 64 levels. As one example, when the bit for expressingthe power headroom is “0” (“000000” when the power headroom is expressedby 6 bits, “0” indicates that the level of the power headroom is“−23≤P_(PH)<−22 dB”.

Meanwhile, the power headroom report may be controlled through aperiodic PHR timer periodicPHR-Timer (hereinafter, referred to as a“periodic timer”) and a prohibition timer prohibitPHR-Timer. A“dl-PathlossChange” value is transmitted through the RRC message tocontrol triggering of the power headroom report by a change in path lossvalue which the UE measures in the downlink and a change in powerbackoff request value (P-MPR) by power management.

The power headroom report may be triggered when at least one of eventsdescribed below occurs.

As one example, in at least one activated serving cell used as path lossreference after the UE last transmits the power headroom power report bysecuring an uplink resource for new transmission, the path loss value(e.g., a path loss estimation value measured by the UE) is more largelychanged and the prohibition timer expires or when the prohibition timerexpires and the path loss value (db) is more largely changed in at leastone activated serving cell used as the path loss reference, the powerheadroom report is triggered. The path loss estimation value may bemeasured by the UE based on the RSRP.

As another example, when the periodic timer expires, the power headroomreport is triggered. Since the power headroom is frequently changed, theUE triggers the power headroom report when the periodic timer expiresand redrives the periodic timer when the power headroom is reportedaccording to the periodic power headroom reporting method.

As yet another example, when a configuration or a reconfigurationassociated with a power headroom reporting operation except forprohibition of use is achieved by the higher layer such as the RRC orthe MAC, the power headroom report is triggered.

As yet another example, when the secondary serving cell in which theuplink is configured is activated, the power headroom report istriggered.

As yet another example, when the UE secures the uplink resource for newtransmission, even any one of the activated serving cells in which theuplink is configured last transmits the power headroom report in uplinkdata transmission or PUCCH transmission through the uplink resource inthe corresponding TTI and thereafter, resource allocation for the uplinktransmission is achieved or when the PUCCH transmission exists in thecorresponding cell and when the change in power backoff request valueP-MPR_(c) is larger than the “dl-PathlossChange” [dB] value after thelast power headroom reporting, the power headroom report is triggered.

As one example of the triggering, when the UE is allocated with theresource for new transmission for the corresponding TTI, three stepsdescribed below are performed.

(1) In first uplink resource allocation for new transmission after lastMAC resetting, the periodic timer starts.

(2) In the case of the power headroom report in which at least one powerheadroom report is triggered after the last power headroom reporttransmission or the transmitted power headroom report is first triggeredand in the case where allocated uplink resources provide a sufficientspace to transmit a power headroom report MAC control element (includingthe extended PHR), 1) when the extended PHR is configured, each uplinkis configured and the type 1 power headroom value is acquired withrespect to the activated serving cell and when the UE is allocated withthe uplink resource for the uplink transmission to the corresponding TTIthrough the corresponding serving cell, the UE acquires a valueequivalent to a P_(CMAX,c) field from the physical layer and generatesand transmits the extended power headroom report MAC control element. 2)When the extended PHR is configured and simultaneous PUCCH-PUSCH isconfigured, the type 2 power headroom value for the primary serving cellis acquired and when the UE transmits the PUCCH to the correspondingTTI, the value equivalent to the P_(CMAX,c) field and generates andtransmits the extended PHR MAC CE. 3) When the extended PHR is notconfigured, the UE acquires the type 1 power headroom value from thephysical layer and generates and transmits the power headroom report MACcontrol element.

(3) The UE starts or restarts the periodic timer, starts or restarts theprohibition timer, and cancels all triggered power headroom reports.

Meanwhile, the extended PHR MAC CE is verified by an LCID in a subheader of an MAC PDU. The extended PHR MAC CE may have various sizes.

Hereinafter, dual connectivity in the small cell will be described.

The UE may receive services through different frequency bands or thesame frequency band from a small base station including only at leastone small cell and a macro base station including only at least onemacro cell. This is also referred to as dual connectivity of the UE. Thedual connectivity may be an operation in which the UE connected with attwo different network points consumes radio resources provided by thenetwork points. A base station having low transmission power such as thesmall base station is also referred to as a low power node (LPN).

A case in which a frequency resource is allocated to the base stationincludes a case in which the base station (hereinafter, referred to asthe small base station) including the small cell and the base station(hereinafter, referred to as the macro base station) including the macrocell use different frequency bands (e.g., a case in which the small basestation uses an F1 frequency band and the macro base station uses an F2frequency band) or a case in which the small base station and the macrobase station have the same frequency band.

FIG. 2 illustrates one example of a dual connectivity situation of UEaccording to an exemplary embodiment.

Referring to FIG. 2, the F2 frequency band is allocated to the macrobase station and the F1 frequency band is allocated to the small basestation. The UE may receive the service from the macro base stationthrough the F2 frequency band and receive the service from the smallbase station through the F1 frequency band.

As such, when the UE is dually connected to the small cell and the macrocell, a method in which the UE is configured to be connected with boththe small cell and the macro cell or operates the connection isproposed.

In a wireless communication system (e.g., an LTE system), a connectionconfiguration between the UE and the cell may be divided into a logicalpath configuration and a radio connection configuration.

The logical path configuration is a path configuration for transmittingdata end-to-end. For example, the logical path configuration includes anEPS bearer configuration, a radio bearer configuration, and the like.

The logical path configuration may not include the radio connectionconfiguration or include a configuration for a partial or entire radioconnection configuration.

The radio connection configuration is a series of configurationsrequired for actually transmitting and receiving wireless communicationdata. For example, the radio connection configuration includes a systeminformation configuration, a PHY/MAC parameter configuration, an RRCconnection configuration, and the like.

An exemplary embodiment includes a method for operating the PHR inrespective radio connection modes as possible under the situation inwhich the dual connectivity between the macro cell and the small cell,and the UE is configured.

In an exemplary embodiment, the logical path configuration will bedescribed as an example through FIGS. 3 and 4 given below. However,exemplary embodiments is not limited thereto. Description of the macrocell and description of the small cell may be changed with each other.

As one example of the dual connectivity, the higher layer (e.g.,RLC/PDCP layer) configured for a data service for the UE exists in onlyone base station according to the base station including the macro cellor the small cell, independently exists for each base station, or existsfor each base station, however, may be connected by a mutual cooperationrelationship or a master-servant relationship.

FIG. 3 is one example of a case in which UE is configured to be duallyconnected with a small base station and a macro base station.

Referring to FIG. 3, the macro base station includes the PDCP, RLC, MAC,PHY layers, but the small base station includes the RLC, MAC, and PHYlayers.

The PDCP layer of the macro base station is connected with the RLC layerof the small base station by using an Xa interface protocol throughbackhaul. Since the PDCP layer is separated from a RAN layer, theseparation is also referred to as a RAN split. Herein, the Xa interfaceprotocol may become an X2 interface protocol defined between the basestations in the LTE system.

The UE receives the service from the small base station by using the F1frequency band as the secondary serving cell and receives the servicefrom the macro base station by using the F2 frequency band as theprimary serving cell.

In the case of the RAN split, signaling through the backhaul physicallyconnected between the macro base station and the small base stationreaches after a comparatively large delay time (e.g., 25 ms to 60 ms),the macro base station may become a schedule for the UE. The reason isthat the scheduler needs to be able to support dynamic resourceallocation by a very short time unit (e.g., 1 ms) in the wirelesscommunication system designed for high-speed transmission, such as theLTE system at present.

In this case, due to the delay time of the signaling through thebackhaul, performance may deteriorate by a difference between ageneration time and an actual application time of scheduling informationfor the dynamic resource allocation in a small base station without thescheduler. Accordingly, a separate scheduler is required even in thesmall base station. This corresponds to case 1 to be described below.

On the contrary, a control plane such as the RRC layer may exist only inthe macro base station due to effectiveness, security, reliability,handover control, and the like of a radio link. In spite of performancedeterioration of resource efficiency through the small base station, thescheduler exists only in the macro base station.

The delay time needs to be at most small until the schedulinginformation is generated by the UE and transferred to the base stationand in the case of control information generated by the UE and providedto the scheduler, the UE transmits uplink transmission including thecontrol information only to one base station (that is, the macro basestation0 including the scheduler. This corresponds to case 2 or 3 to bedescribed below.

Meanwhile, whether the scheduler exists is more closely associated withwhether the RRC layer exists apart from the RAN split/CN split. Whenlayers of the RCL layer or higher exist in all base stations, there is apossibility that scheduling of the MAC/PHY will be performed by aseparate scheduler.

FIG. 4 is another example of a case in which UE is configured to bedually connected with a small base station.

Referring to FIG. 4, each of the small base station and the macro basestation includes the PDCP, RLC, MAC, and PHY layers.

Each of the macro base station and the small base station includes thePDCP layer and each base station may schedule the uplink transmission ofthe UE.

Since, the EPS bearer is separated from a core network, the separationis also referred to as the CN split.

Hereinafter, according to an exemplary embodiment, it is described thatthe UE that is configured to uplink radio connection with two or morebase stations triggers the power headroom report and configures powerheadroom information and reports the configured power headroominformation to each base station, according to downlink and uplinktransmission modes.

It is described that uplink and downlink connections of the UE aredivided into three cases. The uplink and downlink connections of the UEare described in three cases including 1) a case in which a downlinksignal may be simultaneously received from two or more different basestations and the uplink signal may be simultaneously transmitted, 2) acase in which a downlink signal may be simultaneously received from twoor more different base stations, but the uplink signal may betransmitted to only one base station at a time, and 3) a case in whichthe downlink signal may be received from one base station among two ormore different base stations at a time and the uplink signal may betransmitted only to the base station at a time corresponding thereto.

<Case 1: A Case in which the Downlink Signal May be SimultaneouslyReceived from Two or More Different Base Stations and the Uplink SignalMay be Simultaneously Transmitted to Different Base Stations>

FIG. 5 is a flowchart illustrating one example of a procedure in whichUE reports power headroom according to an exemplary embodiment. FIG. 5illustrates an example in which a first base station and a second basestation shares PHR information through backhaul connection (Embodiment1-1).

Referring to FIG. 5, the UE triggers a power headroom report (PHR) basedon a path loss (PathLoss: PL) change for triggering or based on a PHRperiodic timer (S500).

As one example, the UE triggers the PHR based on the path loss changefor triggering.

In detail, after transmitting the PHR most recently (alternatively,immediately previously) based on a current point of time, the UEtriggers the PHR when a situation in which a variation width of a pathloss value (e.g., by the unit of dB) in at least one activated servingcell used as a path loss reference (PLR) is equal to or more than apredetermined value (e.g., a value set to ‘dl-PathlossChange’) occursand a PHR prohibit timer (e.g., prohibitPHR-Timer) expires or when thePHR prohibit timer expires and the situation occurs.

Herein, PLR represents a DL CC which is a criterion for measuring theRSRP value in order to calculate a path loss. The PLR is configured toselect a DL CC more appropriate to the uplink control. This isassociated with a deployment situation.

For example, in the case of different DL CCs defined in the samefrequency band, when all of the DL CCs are transmitted by the same basestation, the path losses for the respective DL CCs will be substantiallysimilar to each other. However, when the DL CCs are transmitted throughbase stations or RRHs which exist at different physical positions,respectively, the path losses for the respective DL CCs will bedifferent from each other. Therefore, the path loss reference formeasuring the path loss may be configured differently according to abase station targeted by a UL CC.

FIG. 6 illustrates one example in which UE triggers a PHR based on achange in path loss value.

Referring to FIG. 6, since a path loss value (M, 650) of the secondaryserving cell is smaller than a predetermined thresholddl-PathlossChange, but a path loss value (K, 610) of the primary servingcell is larger than the predetermined threshold dl-PathlossChange, theUE triggers the PHR when the PHR prohibit timer expires.

In this case, serving cells (that is, the primary serving cell or thesecondary serving cell) in which the path loss value is calculated isone of the serving cells which exist in the macro base station or thesmall base station.

The PLR of the secondary serving cell in sTAG is a DL CC of thesecondary serving cell itself. The PLR of the secondary serving cell inpTAG is the DL CC of the secondary serving cell itself or a DL CC of theprimary serving cell and which CC the corresponding PLR is may bedetermined through the RRC signaling.

FIG. 7 is a diagram illustrating one example of a PLR configurationaccording to an exemplary embodiment.

Referring to FIG. 7, the PLR of SCell2 which is the secondary servingcell in sTAG1 is a DL CC 705 of the PLR itself.

Further, the PLR of SCell1 in pTAG is a DL CC 710 of the PLR itself or aDL CC 715 of PCell.

Meanwhile, the PHR prohibit timer may be configured by the unit of theUE or by the unit of the base station. When the PHR prohibit timer isconfigured based on the base station, the PHR prohibit timer may beconstituted by PHR prohibit timers.

FIG. 8 is a diagram illustrating one example of a configuration of a PHRprohibit timer.

Referring to FIG. 8, a first PHR prohibit timer (Prohibit timer1) 800may be configured with respect to the macro base station and a secondPHR prohibit timer (Prohibit timer2) 805 may be configured with respectto the small base station. The first PHR prohibit timer is configuredwith respect to uplink transmission of the primary time advance grouppTAG and the secondary time advance group sTAG1 included in the macrobase station and the second PHR prohibit timer is configured withrespect to uplink transmission of the secondary time advance groupsTAG2. Further, the PHR prohibit timer may be configured for eachserving cell. The PHR prohibit timer which exists in each serving cellstarts a timer operation when the PHR for the corresponding serving cellis configured and transmitted. For example, when a PHR including PHrelated information for the primary serving cell and the first secondaryserving cell is transmitted, timers configured in the primary servingcell and the first secondary serving cell simultaneously start. However,in the case of the second secondary serving cell not included in thePHR, the time does not start.

Meanwhile, as another example of the PHR triggering criterion in stepS500, the UE triggers the PHR when the PHR periodic timer expires.

In this case, the PHR periodic timer may be configured by the unit ofthe UE or by the unit of the base station. Alternatively, the PHRperiodic timer may be configured similarly to the PHR prohibit timer ofFIG. 8.

Subsequently to step S500, when the PHR transmission criterion issatisfied, the UE transmits the PHR to the first base station (S505). Asone example, since both the macro base station and the small basestation receive the uplink signal from the UE, the first base stationmay be any one of the macro base station and the small base station. Asanother example, the first base station may be a scheduler for a Smallcell SmC and the second base station may be a scheduler for the MAC.

As one example, the ‘PHR transmission criterion’ may be a case in whicha space is provided, which is sufficient to transmit an extended PHR MACCE in which uplink resources allocated in the same TTI with respect tothe serving cells corresponding to each base station include both PH,c(that is, PH for serving cell c) and P_(CMAX,c) (that is, P_(CMAX) forserving cell c) for all activated serving cells. When the PHRtransmission criterion is satisfied, the UE transmits the PHR.

The PHR includes both the PH for the frequency band F1, and PH,c andP_(CMAX,c) for the frequency band F2. The reason is that power headroominformation for the frequency bands F1 and F2 is all required forefficient uplink resource allocation for the UE which is duallyconnected to the small base station and the macro base station under thesituation in which both the small base station and the macro basestation may be the schedulers for the UE.

The first base station may perform uplink scheduling for the UE based onthe PHR.

FIG. 9 illustrates one example of an MAC control element of a PHR whichUE transmits to a first base station or a second base station accordingto an exemplary embodiment. For example, the MAC control element of thePHR may be the extended PHR MAC control element (CE).

Referring to FIG. 9, a C_(i) field 901 to 907 means a secondary servingcell index (SCell Index) “i”, and means that the PH value is reported inthe corresponding secondary serving cell when the C_(i) field is “1” andmeans that the PH value is not reported in the corresponding secondaryserving cell when the C_(i) field is “0”.

Meanwhile, a C₀ field 900 which is configured as an index correspondingto the primary serving cell may indicate that “PH,c” and “P_(CMAX),c”for the primary serving cell are included. That is, the C₀ field 900serves to indicate whether the transmitted PHR MAC CE is associated withthe scheduler including the primary serving cell.

Further, a V field 910 is an indicator indicating whether the PH valueis a PH value based on actual transmission or a PH value for a referenceformat. In the case of the type 1 power headroom report, when ‘V=0’, 0indicates that the PUSCH is actually transmitted and when ‘V=1’, 1indicates that a PUSCH reference format is used. In the case of the type2 power headroom report, when ‘V=0’, 0 indicates that the PUCCH isactually transmitted and when ‘V=1’, 1 indicates that a PUCCH referenceformat is used. When ‘V=0’ commonly with respect to the type 1 powerheadroom report and the type 2 power headroom report, 0 indicates thatan associated P_(CMAX,c) field exists and when ‘V=1’, 1 indicates thatthe associated P_(CMAX),c field is omitted.

Further, a PH field 915 may be a field for a power headroom value and 6bits.

Further, a P field indicates whether the UE applies power backoff(P-MPR) by power management and as one example, when the P_(CMAX),cfield value has a different value due to the power backoff, ‘P=1’ isconfigured.

In addition, the P_(CMAX),C field indicates P_(CMAX),c or {tilde over(P)}_(CMAX,c) used for calculating the PH field and the field value mayexist or not.

Subsequently to step S505, the first base station transfers the PHR fromthe first base station to the second base station through the backhaul(S510).

The PHR includes both the PH for the frequency band F1 and the PH forthe frequency band F2.

As one example, when the first base station is the macro base station,the second base station is the small base station.

As another example, when the first base station is the small basestation, the second base station is the macro base station.

The second base station may perform uplink scheduling for the UE basedon the PHR.

FIG. 10 is a flowchart illustrating another example of a procedure inwhich UE reports power headroom according to an exemplary embodiment.FIG. 10 illustrates an example in which the UE directly transmits thePHR to the first base station and the second base station regardless ofconnection (e.g., backhaul) between the first base station and thesecond base station (Embodiment 1-2). This is also referred to as directsignaling.

Referring to FIG. 10, the UE triggers the power headroom report (PHR)based on the path loss change for triggering or based on the PHRperiodic timer (S1000).

As one example, the UE triggers the PHR based on the path loss changefor triggering.

As another example, the UE triggers the PHR based on the case in whichthe PHR periodic timer expires for triggering. In this case, the PHRperiodic timer may be configured by the unit of the UE or by the unit ofthe base station or similarly to the PHR prohibit timer.

Subsequently to step S1000, when the PHR transmission criterion issatisfied, the UE duplicatively transmits the PHR to the first basestation and the second base station (S1005).

The duplicative transmission includes simultaneous transmission andnon-simultaneous transmission. The simultaneous transmission means thatthe PHR is transmitted when the UE receives uplink resource allocationinformation from all base stations (e.g., the small base station and themacro base station) with respect to the same TTI or is configured andthe non-simultaneous transmission means that the UE transmits the PHR tothe base station which receives the uplink resource allocationinformation or is configured.

As one example, when one timer may be configured for each UE, thesimultaneous transmission may be performed or when one timer may beconfigured for each base station, the non-simultaneous transmission maybe performed.

As another example, in the duplicative transmission, the UE may transmitthe PHR to a plurality of base stations through one specific cell. Inthis case, one specific cell may be a cell in which a specific schedulerexists.

That is, the PHR transmission to the first base station and the PHRtransmission to the second base station may be simultaneously performed,or the PHR transmission to the first base station may be first performedor the PHR transmission to the second base station may be firstperformed.

As yet another example, the first base station may be one of the macrobase station and the small base station. As still another example, thefirst base station may be the scheduler for the Small cell SmC and thesecond base station may be the scheduler for the MAC.

Meanwhile, as one example, the ‘PHR transmission criterion’ may be acase in which the space is provided, which is sufficient to transmit theextended PHR MAC CE in which uplink resources allocated in the same TTIwith respect to the serving cells corresponding to each base stationinclude both PH,c and P_(CMAX,c) for all activated serving cells. Whenthe PHR transmission criterion is satisfied, the UE transmits the PHR.

The PHR includes both the PH for the frequency band F1 and the PH forthe frequency band F2. As one example, the MAC control element of thePHR is illustrated in FIG. 9.

Each of the first base station and the second base station may performthe uplink scheduling for the UE based on the PHR.

<Case 2: A Case in which the Downlink Signal May be SimultaneouslyReceived from Two or More Different Base Stations, but the Uplink SignalMay be Transmitted to Only One Base Station at a Time>

FIG. 11 is a flowchart illustrating yet another example of a procedurein which UE reports power headroom according to an exemplary embodiment.FIG. 11 illustrates an example in which the second base station havingan uplink physical layer scheduling authority schedules the first basestation having no uplink physical layer scheduling authority throughbackhaul connection (Embodiment 2-1). For example, the example is thecase of the RAN split illustrated in FIG. 3.

As one example, the first base station may be the scheduler for the MAC.

As another example, the PHR may be transmitted when the UE performs anuplink time division multiplexing (TDM) operation.

As yet another example, the second base station may be the macro basestation and the first base station may be the small base station.

Referring to FIG. 11, the UE triggers the power headroom report (PHR)based on the path loss change for triggering or based on the PHRperiodic timer (S1100).

As one example, the UE triggers the PHR based on the path loss changefor triggering.

As another example, the UE triggers the PHR based on the case in whichthe PHR periodic timer expires for triggering. In this case, the PHRperiodic timer may be configured by the unit of the UE or by the unit ofthe base station or similarly to the PHR prohibit timer.

As yet another example, the downlink criterion for triggering the PHRmay be switched together according to uplink switching. That is,downlink monitoring is not performed according to a consecutive time,but is inconsecutive and an operation for triggering the PHR isperformed based on only a time when each downlink is operated.

Subsequently to step S1100, when the PHR transmission criterion issatisfied, the UE transmits the PHR to the first base station (S1105) ortransmits the PHR to the second base station (S1106). S1105 and S1106are performed in a time sequence in FIG. 11, but this is just oneexample and S1106 may be performed earlier than S1105, but S1105 andS1106 may not be simultaneously performed.

Since the UE may perform the uplink transmission to only one basestation at a time, the UE transmits the PHR to one base station of thefirst base station and the second base station through switching 1150.

Herein, the PHR transmitted to the first base station is the PHR for thefrequency band F1 and the PHR transmitted to the second base station isthe PHR for the frequency band F2.

FIG. 12 illustrates one example of an uplink frame structure including aPHR which UE transmits to a first base station or a second base stationaccording to an exemplary embodiment.

Referring to FIG. 12, the UE transmits a PHR 1205 for the frequency bandF2 to the second base station by using one (e.g., subframe #2) ofsubframe#0 to subframe #4 of an uplink frame. In this case, a first PHRprohibit timer (Prohibit timer1) 1255 and a first PHR periodic timer(Periodic timer1) 1260 may be configured with respect to PCell orScell1.

FIG. 13 illustrates one example of a PHR MAC CE which UE transmits to abase station including a primary serving cell.

Referring to FIG. 13, a primary serving cell index 1305 and an SCell1index 1310 are ‘1’. This indicates that the PH values are reported inthe primary serving cell and the Scell1.

Further, a V field 1315 for primary serving cell type 2 power headroomis ‘1’. This indicates that the PH uses the PUCCH reference format.

Further, the PHR MAC CE is constituted by only 6 bytes (means 8 bits,that is, 1 byte). The reason is that only the PHR for the frequency bandF2 is transmitted to the second base station including the primaryserving cell.

Meanwhile, in FIG. 12, the UE transmits a PHR 1210 for the frequencyband F1 to the first base station by using one (e.g., subframe #8) ofsubframe#5 to subframe #9 of the uplink frame. In this case, a secondPHR prohibit timer (Prohibit timer2) 1265 and a second PHR periodictimer (Periodic timer2) 1270 may be configured with respect to Scell2.

FIG. 14 illustrates one example of a PHR MAC CE which UE transmits to abase station not including a primary serving cell.

Referring to FIG. 14, a primary serving cell index 1405 is ‘0’ and anSCell2 index 1410 is ‘1’. This indicates that the PH value is reportedin the Scell2.

Further, the PHR MAC CE is constituted by 3 bytes. The reason is thatonly the PHR for the frequency band F1 is transmitted to the first basestation. That is, an activated serving cell that belongs to another basestation is excluded from PHR components.

Consequently, the UE transmits the uplink frame to alternately transmitthe PHR for the frequency band F2 and the PHR for the frequency band F1.

When the first base station has no physical layer scheduling authorityand the second base station has the uplink physical layer schedulingauthority, the first base station may not perform the uplink schedulingfor the UE in spite of receiving the PHR. Since the second base stationreceives only the PHR for the frequency band F2, the second base stationmay perform the uplink scheduling for the UE until receiving the PHR forthe frequency band F1.

Subsequently to step S1105, the first base station transfers the PHR forthe first base station to the second base station through the backhaul(S1110). As a result, the second base station may receive both the PHRsfor the frequency bands F1 and F2. Further, the second base station mayperform the uplink scheduling for the UE based on the PHR.

Subsequently to step S1110, the second base station may transferscheduling to information for the UE to the first base station (S1115).

As one example, in the case of the RAN split illustrated in FIG. 3, thePDCP layer of the second base station is connected with the RLC layer ofthe first base station by the Xa interface protocol through the backhaulto transfer the scheduling information.

FIG. 15 is a flowchart illustrating still another example of a procedurein which UE reports power headroom according to an exemplary embodiment.FIG. 15 is an example in which the second base station having an uplinkphysical layer scheduling authority may not transfer the PHR bybackhaul-connecting the first base station having no uplink physicallayer scheduling authority, and the UE wirelessly transmits the PHR forall serving cells to the second base station (Embodiment 2-2).

As another example, in the case of the RAN split illustrated in FIG. 3,since the second base station schedules the first base station, thesecond base station is macro base station and the first base station isa small base station.

Referring to FIG. 15, the UE triggers the PHR based on the path losschange for triggering or based on the PHR periodic timer (S1500).

As one example, the UE triggers the PHR based on the path loss changefor triggering.

As another example, the UE triggers the PHR based on the case in whichthe PHR periodic timer expires for triggering. In this case, the PHRperiodic timer may be configured by the unit of the UE or by the unit ofthe base station or similarly to the PHR prohibit timer.

In this case, the PHR periodic timer may be configured by the unit ofthe UE or by the unit of the base station. Alternatively, the PHRperiodic timer may be configured similarly to the PHR prohibit timer ofFIG. 8. [0232] As yet another example, the downlink criterion fortriggering the PHR may be switched together according to uplinkswitching.

Subsequently to step S1500, the UE stores the PHR for the frequency bandF1 therein (S1505), and when the PHR transmission criterion issatisfied, the UE transmits the PHR for the frequency band F1 or the PHRfor the frequency bands F1 and F2 to the second base station (S1010).

FIG. 16 illustrates one example of an uplink frame structure including aPHR which UE transmits to a second base station according to anexemplary embodiment.

Referring to FIG. 16, even though the PHR transmission for the frequencyband F1 is triggered due to the TDM, the UE may not transmit the PHR forthe frequency band F1 by using one (for example, subframe #2) 1605 ofsubframe #0 to subframe #4 in the uplink frame.

The reason is that in the TDM type, the PHR for F1 and the PHR for F2are sequentially transmitted.

Instead, the UE constitutes the PHR for the frequency band F1 to savethe PHR therein.

In order to transmit all of the triggered PHRs to the macro basestation, in a initially configured uplink resource 1610 (for example,subframe #8), the UE transmits the PHR for the frequency band F1 or thePHRs for the frequency bands F1 and F2.

As an example, regardless of whether to transmit the PHR for thefrequency band F2, the UE may irrespectively transmit the PHR for thefrequency band F1. Of course, when the PHR for the frequency band F2 istriggered before, the PHR for the frequency band F1 may be transmittedtogether.

FIG. 17 illustrates yet another example of the PHR MAC CE which UEtransmits to the base station.

Referring to FIG. 17, a primary serving cell index 1705 is ‘0’ and anindex 1710 for SCell2 and SCell2 is ‘1’. This indicates that the PHvalues are reported in the primary serving cell, the SCell2, and theSCell2.

Further, the PHR MAC CE is constituted by 8 bytes, in second to sixthbytes, a PHR 1720 for the frequency band F2 is included, and in seventhto eighth bytes, a PHR 1725 for the frequency band F1 is included.

That is, only activated serving cells belonging to another base stationmay be included in the PHR MAC CE. However, the transmitted PHRinformation does not include “PHR,c” or “P_(CMAX),c” valuessimultaneously calculated with respect to all activated cells in thesame TTI. The PHR information is constituted by the PHR,c and P_(CMAX),cvalues calculated only when each base station and the UE are connectedto each other in different TTIs with uplink.

Consequently, the UE transmits the uplink frame to simultaneouslytransmit the PHR for the frequency band F1 regardless of the PHR for thefrequency band F2.

As another example, when the PHR for the frequency band F2 istransmitted (alternatively, the PHR for the frequency band F2 istriggered), the UE may transmit the PHR for the frequency band F1 to thesecond base station together with the PHR for the frequency band F2.That is, in an interval when uplink transmission for the base stationwith a scheduler is possible, when the PHR for the base station(alternatively, a base station with the primary serving cell) withoutthe scheduler is triggered and an uplink resource capable oftransmitting the PHR is ensured, the PHR for the base station withoutthe scheduler may be configured to be transmitted together.

FIG. 18 illustrates yet another example of a PHR MAC CE which UEtransmits to a base station according to an exemplary embodiment.

Referring to FIG. 18, an index 1810 for SCell1 and SCell2 is ‘1’. Thisindicates that the PH values are reported in the SCell1 and the SCell2.

Further, the PHR MAC CE is constituted by 8 bytes, in second to sixthbytes, a PHR 1820 for the frequency band F2 is included, and in seventhto eighth bytes, a PHR 1825 for the frequency band F1 is included.

That is, only activated serving cells belonging to another base stationmay be included in the PHR MAC CE. However, the transmitted PHRinformation does not include “PHR,c” or “P_(CMAX),c” valuessimultaneously calculated with respect to all activated cells in thesame TTI. The PHR information is constituted by the PHR,c and P_(CMAX),cvalues calculated only when each base station and the UE are connectedto each other in different TTIs with uplink.

Consequently, the UE transmits the uplink frame to simultaneouslytransmit the PHR for the frequency band F1 together with the PHR for thefrequency band F2.

Subsequently to step S1510, the second base station may transferscheduling information for the UE to the first base station (S1515).

For example, even though the PHR can not be transferred because thebackhaul between the first base station and the second base station isnon-ideal, in the case of transferring scheduling information (forexample, UL grant), the scheduling information for the UE may betransferred from the second base station to the first base station.

FIG. 19 is a flowchart illustrating another example of a procedure inwhich UE reports power headroom according to an exemplary embodiment.FIG. 19 illustrates an example in which the UE directly transmits thePHR to the first base station and the second base station regardless ofconnection (e.g., backhaul) between the first base station and thesecond base station (Embodiment 2-3). This is referred to as directsignaling.

As one example, the first base station may be one of the macro basestation and the small base station. As another example, the first basestation may be the scheduler for SmC and the second base station may bethe scheduler for the MAC.

Referring to FIG. 19, the UE triggers the PHR based on the path losschange for triggering or based on the PHR periodic timer (S1900).

As one example, the UE triggers the PHR based on the path loss changefor triggering.

As another example, the UE triggers the PHR based on the case in whichthe PHR periodic timer expires for triggering. In this case, the PHRperiodic timer may be configured by the unit of the UE or by the unit ofthe base station or similarly to the PHR prohibit timer.

Subsequently to step S1900, when the PHR transmission criterion issatisfied, the UE transmits the PHR for the frequency band F1 to thefirst base station (S1905) and transmits the PHR for the frequency bandF2 to the second base station (S1910). In this case, since the PHRtransmission to the first base station and the PHR transmission to thesecond base station may not be simultaneously performed, the PHRtransmission to the first base station may be first performed or the PHRtransmission to the second base station may be first performed. That is,switching 1950 may be performed.

When an object performing uplink physical layer scheduling exists in themacro base station and the small base station, the PHR information isconstituted by only the cells in the corresponding base station to betransmitted.

As one example, the first base station and the second base stationconfigure different timers, respectively. For each base station, valuesand operations of a PHR prohibition timer and a PHR periodic timer areindependent.

As another example, information on cells included in different basestations may not be included in the PHR. That is, in the PHR transmittedto the first base station, information on the frequency band F2 is notincluded and in the PHR transmitted to the second base station,information on the frequency band F1 is not included.

As yet another example, information on cells included in different basestations may be included in a virtual PHR form. That is, in the PHRtransmitted to the first base station, information on the frequency bandF2 is included in the virtual PHR form and in the PHR transmitted to thesecond base station, information on the frequency band F1 is included inthe virtual PHR form. Here, the virtual PHR means a PHR withoutP_(CMAX),c.

Each of the first base station and the second base station may performthe uplink scheduling for the UE based on the PHR.

As one example, the MAC control element of the PHR transmitted to thefirst base station is illustrated in FIG. 14.

As another example, the MAC control element of the PHR transmitted tothe second base station is illustrated in FIG. 13.

<Case 3: A Case in which the Downlink Signal May be Received from OneBase Station at a Time in Two or More Different Base Stations and theUplink Signal May be Transmitted to Only the Base Station at a TimeCorresponding Thereto>

The UE triggers the PHR based on the path loss change for triggering orbased on the PHR periodic timer.

In this case, the PHR triggering may independently exist for eachconnection relation between the small base station and the macro basestation. That is, in the case of the uplink simultaneous transmission,when the PHR is triggered with respect to the serving cell included inat least one base station, the serving cells included in all of the basestations may be included in the PHR. On the contrary, when the downlinkand the uplink operate with TDM, the downlink PHR triggering does notinfluence the PHR operation for the serving cells included in differentbase stations.

As an example, it is a case where a small base station without uplinkphysical layer scheduling and a macro base station with uplink physicallayer scheduling are configured through backhaul connection.

When the PHR is triggered and the PHR transmission criterion issatisfied, the UE transmits the PHR for the frequency band F1 to thefirst base station or transmits the PHR for the frequency band F2 to thesecond base station. Since the UE may perform the uplink transmission toonly one base station at a time, the UE transmits the PHR to one basestation of the first base station and the second base station throughswitching. In this case, the first base station transfers the PHR forthe frequency band F1 through the backhaul and based on the PHRs for thefrequency bands F1 and F2, the second base station transfers thescheduling information on the user equipment to the first base station.

As one example, the uplink frame including the PHR is illustrated inFIG. 12.

As another example, a PHR MAC CE which the UE transmits to the basestation including the primary serving cell is illustrated in FIG. 13.

As yet another example, a PHR MAC CE which the UE transmits to the basestation without including the primary serving cell is illustrated inFIG. 14.

Meanwhile, as another example, there is a case where the small basestation and the macro base station may not transfer the PHR informationdue to non-ideal backhaul connection (Embodiment 3-2). The UE wirelesslytransmits the PHR for all the serving cells to the second base station.

When the PHR is triggered and the PHR transmission criterion issatisfied, the UE stores the PHR for the frequency band F1 therein andtransmits the PHR for the frequency band F1 or the PHRs for thefrequency bands F1 and F2 to the second base station. The second basestation transfers the scheduling information for the UE to the firstbase station.

For example, in order to transmit all of the triggered PHRs to the macrobase station, in a initially configured uplink resource 1610 (forexample, subframe #8), the UE transmits the PHR for the frequency bandF1 or the PHRs for the frequency bands F1 and F2.

In this case, as an example, regardless of whether to transmit the PHRfor the frequency band F2, the UE may irrespectively transmit the PHRfor the frequency band F1. Of course, when the PHR for the frequencyband F2 is triggered before, the PHR for the frequency band F1 may betransmitted together.

Alternatively, as another example, when the PHR for the frequency bandF2 is transmitted (alternatively, the PHR for the frequency band F2 istriggered), the UE may transmit the PHR for the frequency band F1 to thesecond base station together with the PHR for the frequency band F2.That is, in an interval when uplink transmission for the base stationwith a scheduler is possible, when the PHR for the base station(alternatively, a base station with the primary serving cell) withoutthe scheduler is triggered and an uplink resource capable oftransmitting the PHR is ensured, the PHR for the base station withoutthe scheduler may be configured to be transmitted together.

As one example, the uplink frame including the PHR is illustrated inFIG. 16.

As another example, the PHR MAC CE which the UE transmits to the basestation is illustrated in FIG. 17 or 18.

Meanwhile, as yet another example, there is a case (Embodiment 3-3) inwhich each of the small base station and the macro base station mayperform the uplink physical layer scheduling. The UE directly transmitsthe PHR to the first base station and the second base station regardlessof connection (e.g., backhaul) between the first base station and thesecond base station.

When the PHR transmission criterion is satisfied, the UE transmits thePHR for the frequency band F1 to the first base station and the PHR forthe frequency band F2 to the second base station. In this case, since asubject that performs the uplink physical layer scheduling exists ineach of the macro base station and the small base station, each PHRinformation is configured and transmitted only in cells in thecorresponding base station. Each of the first base station and thesecond base station may perform the uplink scheduling for the UE basedon the PHR.

As one example, the first base station and the second base stationconfigure different timers, respectively.

As another example, information on cells included in different basestations may not be included in the PHR. That is, in the PHR transmittedto the first base station, information on the frequency band F2 is notincluded and in the PHR transmitted to the second base station,information on the frequency band F1 is not included.

As yet another example, information on cells included in different basestations may be included in a virtual PHR form. That is, in the PHRtransmitted to the first base station, information on the frequency bandF2 is included in the virtual PHR form and in the PHR transmitted to thesecond base station, information on the frequency band F1 is included inthe virtual PHR form.

As one example, the MAC control element of the PHR transmitted to thefirst base station is illustrated in FIG. 14.

As another example, the MAC control element of the PHR transmitted tothe second base station is illustrated in FIG. 13.

FIG. 20 is a flowchart illustrating one example of an operation of UEwhich reports power headroom according to an exemplary embodiment.

Referring to FIG. 2, uplink wireless connection of UE with two ore moredifferent base stations is configured as dual connectivity (S2000). Thedual connectivity may mean newly dual connectivity or the existing dualconnectivity state.

In the dual connectivity of the UE, there are three cases including 1) acase in which a downlink signal may be simultaneously received from twoor more different base stations and the uplink signal may besimultaneously transmitted, 2) a case in which a downlink signal may besimultaneously received from two or more different base stations, butthe uplink signal may be transmitted to only one base station at a time,and 3) a case in which the downlink signal may be received from one basestation among two or more different base stations at a time and theuplink signal may be transmitted only to the base station at a timecorresponding thereto.

Subsequently to step S2000, the UE triggers a power headroom report(S2005).

As one example, the UE triggers the power headroom report based on apath loss change for triggering. In detail, after transmitting the PHRmost recently (alternatively, immediately previously) based on a currentpoint of time, the UE triggers the PHR when a situation in which avariation width of a path loss value (e.g., by the unit of dB) in atleast one activated serving cell used as a path loss reference (PLR) isequal to or more than a predetermined value (e.g., a value set to‘dl-PathlossChange’) occurs and a PHR prohibit timer (e.g.,prohibitPHR-Timer) expires or when the PHR prohibit timer expires andthe situation occurs. The PHR prohibit timer may be configured by theunit of the UE or by the unit of the base station. When the PHR prohibittimer is configured based on the base station, the PHR prohibit timermay be constituted by PHR prohibit timers.

As another example, the UE may trigger the power headroom report basedon a PHR periodic timer. In this case, the PHR periodic timer may beconfigured by the unit of the UE or by the unit of the base station.Alternatively, the PHR periodic timer may be configured similarly to thePHR prohibit timer.

Subsequently to step S2005, when a PHR transmission criterion issatisfied, the UE configures power headroom information and reports theconfigured power headroom information to the base station (S2010).

In this case, the ‘PHR transmission criterion’ may be a case in which aspace is provided, which is sufficient to transmit an extended PHR MACCE in which uplink resources allocated in the same TTI with respect tothe serving cells corresponding to each base station include both PH,c(that is, PH for serving cell c) and P_(CMAX,c) (that is, P_(CMAX) forserving cell c) for all activated serving cells.

As one example (case 1) of step S2010, when the UE may simultaneouslyreceive downlink signals from two or more different base stations andsimultaneously transmit uplink signals, the UE may transmit a PHRincluding both the PH for the frequency band F1 and the PH and P_(CMAX)for the frequency band F2 to a first base station when the PHRtransmission criterion is satisfied. A MAC control element of the PHRmay be illustrated in FIG. 9. In this case, the first base station maytransfer the PHR including both the PH for the frequency band F1 and thePH for the frequency band F2 to a second base station through backhaul.

Alternatively, as another example, the UE may directly transmit the PHRto each of the first base station and the second base station.

Alternatively, as another example, the UE may duplicatively transmit thePHR to the first base station and the second base station. Theduplicative transmission includes simultaneous transmission andnon-simultaneous transmission. When one timer may be configured for eachUE, the simultaneous transmission may be performed or when one timer maybe configured for each base station, the non-simultaneous transmissionmay be performed.

As another example (case 2) of step S2010, when wireless connection withtwo or more different base stations is configured with respect to radioconnection and the downlink signals may be simultaneously received, butthe uplink signal is transmitted to only one base station at a time, theUE transmits the PHR to one base station (e.g., the first base station0of the first base station and the second base station when the PHRtransmission criterion is satisfied. In this case, the first basestation may transfer the PHR for the frequency band F1 to the secondbase station through the backhaul and the second base station maytransfer scheduling information for the UE to the first base station.Herein, the PHR transmitted to the first base station is the PHR for thefrequency band F1 and the PHR transmitted to the second base station isthe PHR for the frequency band F2. An uplink frame structure includingthe PHR which the UE transmits to the first base station or the secondbase station may be illustrated in FIG. 12, the PHR MAC CE which the UEtransmits to the base station including a primary serving cell may beillustrated in FIG. 13, and the PHR MAC CE which the UE transmits to abase station not including the primary serving cell may be illustratedin FIG. 14.

Alternatively, as another example, when the second base station havingan uplink physical layer scheduling authority may not transfer the PHRto the first base station having no uplink physical layer schedulingauthority through backhaul connection, the UE may wirelessly transmitthe PHRs for all serving cells to the second base station.

Alternatively, as another example, the UE may store the PHR for thefrequency band F1 and when the PHR transmission criterion is satisfied,the UE may transmit the PHR for the frequency band F1 or the PHRs forthe frequency bands F1 and F2 to the second base station. In this case,the UE may irrelevantly transmit the PHR for the frequency band F1regardless of transmission of the PHR for the frequency band F2. Whenthe PHR for the frequency band F2 is previously triggered, the PHR forthe frequency band F2 may be transmitted together with the is PHR forthe frequency band F1. The PHR MAC CE which the UE transmits to the basestation may be illustrated in FIG. 17 or 18.

Alternatively, as another example, the UE may directly transmit the PHRto each of the first base station and the second base station. That is,when the PHR transmission criterion is satisfied, the UE transmits thePHR for the frequency band F1 to the first base station and the PHR forthe frequency band F2 to the second base station. In this case, sincethe PHR transmission to the first base station and the PHR transmissionto the second base station may not be simultaneously performed, the PHRtransmission to the first base station may be first performed or the PHRtransmission to the second base station may be first performed. Further,information on cells included in another base station may not beincluded in the PHR or may be included in a virtual PHR form.

As another example (case 3) of step S2010, when the downlink signal maybe received from one base station among two or more different basestations at a time and the uplink signal may be transmitted to only thebase station at a time corresponding thereto, the UE transmits the PHRfor the frequency band F1 to the first base station or transmits the PHRfor the frequency band F2 to the second base station through switching.In this case, the first base station transfers the PHR for the frequencyband F1 to the second base station through the backhaul and the secondbase station transfers the scheduling information for the UE to thefirst base station based on the PHRs for the frequency bands F1 and F2.

Alternatively, as another example, when the small base station and themacro base station may not transfer the PHR information due to abnormalbackhaul connection, the UE stores the PHR for the frequency band F1therein and transmits the PHR for the frequency band F1 or the PHRs forthe frequency band F1 and the frequency band F2 to the second basestation.

In this case, the second base station transfers the schedulinginformation for the UE to the first base station.

Alternatively, as another example, when each of the small base stationand the macro base station may perform the uplink physical scheduling,the UE directly transmits the PHR to each of the first base station andthe second base station. That is, since a subject that performs theuplink physical layer scheduling exists in each of the macro basestation and the small base station, each PHR information is configuredand transmitted only in cells in the corresponding base station. In thiscase, information on cells included in another base station may not beincluded in the PHR or may be included in a virtual PHR form.

FIG. 21 is one example of a flowchart illustrating an operation of abase station according to an exemplary embodiment. The base station maybe the small base station or the macro base station.

Referring to FIG. 21, uplink wireless connection of two ore moredifferent base stations with UE is configured as dual connectivity(S2100). The dual connectivity may mean newly dual connectivity or theexisting dual connectivity state.

Subsequently to step S2100, when the PHR transmission criterion issatisfied, the base station receives the power headroom information fromthe UE (S2105).

As one example (case 1) of step S2105, in the case where the UE maysimultaneously receive the downlink signals from two or more differentbase stations and simultaneously transmit the uplink signals, when thebase station receives the PHR including both the PH for the frequencyband F1 and the PH and P_(CMAX) for the frequency band F2 from the UE,the base station transfers the PHR including both the PH for thefrequency band F1 and the PH for the frequency band F2 to the secondbase station. The MAC control element of the PHR may be illustrated inFIG. 9.

As another example (case 2) of step S2105, in the case where radioconnection with two or more different base stations is configured withrespect to uplink and the downlink signals may be simultaneouslyreceived, but the uplink signal is transmitted to only one base stationat a time, when the base station receives the PHR from the UE, the basestation transfers the PHR for the frequency band F1 which is a servingfrequency band to the second base station through the backhaul andreceives the scheduling information for the UE from the second basestation.

Alternatively, as another example, when the second base station havingthe uplink physical layer scheduling authority may not transfer the PHRto the first base station having no uplink physical layer schedulingauthority through the backhaul connection, the base station wirelesslyreceives the PHRs for all serving cells from the UE.

Alternatively, as another example, the base station may receive the PHRfor the frequency band F2 from the UE together with the PHR for thefrequency band F1 which the UE stores therein.

As another example (case 3) of step S2010, when the downlink signal maybe received from one base station among two or more different basestations at a time and the uplink signal may be transmitted to only thebase station at a time corresponding thereto, the base station receivesthe PHR for the frequency band F1 which is the serving frequency bandthrough the switching and transfers the PHR for the frequency band F1 tothe second base station through the backhaul. When the second basestation separately receives the PHR for the frequency band 2 which isthe serving frequency band, the base station receives the schedulinginformation for the UE from the second base station.

FIG. 22 is a block diagram illustrating an example of an apparatus oftransmitting and receiving power headroom reports according to anexemplary embodiment.

Referring to FIG. 22, UE 2200 includes a receiving unit 2205, a controlunit 2210, or a transmitting unit 2220. The control unit 2210 mayfurther include a triggering unit 2212 or a PHR configuration unit 2215.

In the UE 2200, uplink wireless connection with two or more basestations is configured by dual connectivity.

The triggering unit 2212 triggers power headroom reports based on pathloss change or a PHR periodic timer.

The HR configuration unit 2215 constitutes power headroom information.

The transmitting unit 2220 reports the power headroom information to thebase station 2250.

In the case where the UE 2200 may simultaneously receive a downlinksignal from two or more different base stations and simultaneouslytransmit an uplink signal, the transmitting unit 2220 may transmit a PHRincluding a PH for the frequency band F1, a PH for the frequency bandF2, and P_(CMAX) to the first base station. Alternatively, thetransmitting unit 2220 may transmit the PHR to the first base stationand the second base station, respectively. Alternatively, thetransmitting unit 2220 may redundantly transmit the PHR to the firstbase station and the second base station.

Wireless connection with two or more different base stations for uplinkis configured and simultaneously, the downlink signal may be received,but when the uplink signal is transmitted to only one base station at atime, the transmitting unit 2220 transmits the PHR to one (for example,the first base station) of the first base station and the second firstbase station.

The transmitting unit 2220 transmits the PHR to either the first basestation or the second first base station through switching, and the PHRtransmitted to the first base station is the PHR for the frequency bandF1 and the PHR transmitted to the second base station is the PHR for thefrequency band F2. When the second base station having an uplinkphysical layer scheduling authority may not transfer the PHR bybackhaul-connecting the first base station having no uplink physicallayer scheduling authority, the transmitting unit 2220 transmits the PHRfor all serving cells to the second base station. Alternatively, basedon the PHR for the frequency band F1 stored therein, the transmittingunit 2220 may transmit the PHR for the frequency band F1 or the PHR forthe frequency bands F1 and F2 to the second base station. Alternatively,the transmitting unit 2220 may transmit the PHR for the frequency bandF1 to the first base station or the PHR for the frequency band F2 to thesecond base station.

In the case where the downlink signal may be received from one basestation of two or more different base stations at a time and the uplinksignal may be transmitted to only the base station at a timecorresponding thereto, the transmitting unit 2220 transmits the PHR forthe frequency band F1 to the first base station or the PHR for thefrequency band F2 to the second base station through switching.Alternatively, in the case where the small base station and the macrobase station may not transfer the PHR information due to non-idealbackhaul connection, based on the PHR for the frequency band F1 storedtherein, the transmitting unit 2220 may transmit the PHR for thefrequency band F1 or the PHR for the frequency bands F1 and F2 to thesecond base station. Alternatively, in the case where the small basestation and the macro base station may perform uplink physical layerscheduling, respectively, the transmitting unit 2220 transmits the PHRinformation constituted by only cells in the corresponding base stationto the first base station and the second base station, respectively.

Meanwhile, the base station 2250 includes a transmitting unit 2255 and areceiving unit 2260.

In two or more different base stations 2250, uplink wireless connectionwith the UE 2200 is configured by dual connectivity.

The receiving unit 2260 receives power headroom information from the UE2200.

In the case where the UE 2200 may simultaneously receive a downlinksignal from two or more different base stations and simultaneouslytransmit an uplink signal, the receiving unit 2260 may receive a PHRincluding a PH for the frequency band F1, a PH for the frequency bandF2, and P_(CMAX) from the UE 2200. In this case, the transmitting unit2255 transmits the PHR including the PH for the frequency band F1 andthe PH for the frequency band F2 to the second base station throughbackhaul.

The wireless connection with two or more different base stations withuplink is to configured and simultaneously, the downlink signal may bereceived, but when the uplink signal is transmitted to only one basestation at a time, the receiving unit 2260 receives the PHR from the UE2200 and the transmitting unit 2255 transmits the PHR for the frequencyband F1 as the serving frequency band through backhaul to the secondbase station, and the receiving unit 2260 receives schedulinginformation on the UE 2200 from the second base station. Alternatively,when the PHR may not be received from the second base station having theuplink physical layer scheduling authority through backhaul connection,the receiving unit 2260 wirelessly receives the PHR for all servingcells from the UE 2200. Alternatively, the receiving unit 2260 may alsoreceive from the UE 2200 the PHR for the frequency band F2 together withthe PHR for the frequency band F1 stored in the UE 2200.

In the case where the downlink signal may be received from one basestation of two or more different base stations at a time and the uplinksignal may be transmitted to only the base station at a timecorresponding thereto, the receiving unit 2260 receives the PHR for thefrequency band F1 as the serving frequency band through switching andthe transmitting unit 2255 transmits the PHR for the frequency band F1to the second base station through backhaul. When the second basestation separately receives the PHR for the frequency band F2 as theserving frequency band, the receiving unit 2260 receives the schedulinginformation on the UE 2200 from the second base station.

The inventive concept described as above is not limited by theaforementioned exemplary embodiments and the accompanying drawingsbecause it will be apparent to those skilled in the art that varioussubstitutions, modifications, and changes can be made within the scopewithout departing from the technical spirit of the present invention.

In the aforementioned exemplary system, methods have been describedbased on flowcharts as a series of steps or blocks, but the methods arenot limited to the order of the steps of the present invention and anystep may occur in a step or an order different from or simultaneously asthe aforementioned step or order. Further, it can be appreciated bythose skilled in the art that steps shown in the flowcharts are notexclusive and other steps may be included or one or more steps do notinfluence the scope of the present invention and may be deleted.

What is claimed is:
 1. A method for transmitting a power headroom report(PHR) by a user equipment performing wireless communication based ondual connectivity, the method comprising: triggering the PHR based on atleast one of a path loss change or a periodic timer; and transmitting atleast one PHR to a first base station and a second base stationaccording to the dual connectivity, wherein the at least one PHRcomprises both a first power headroom (PH) for a first frequency bandthat is a serving frequency of the first base station and a second PHfor a second frequency band that is the serving frequency of the secondbase station, when the user equipment simultaneously receives downlinksignals from the first base station and the second base station andsimultaneously transmits an uplink signal, and wherein the transmittingof the at least one PHR comprises transmitting the at least one PHR fora first frequency band to the second base station when the at least onePHR for the second base station is triggered based on the user equipmentreceiving the downlink signals from one base station of the first basestation and the second base station at a time and transmitting an uplinksignal to only the corresponding base station at a time.
 2. The methodof claim 1, wherein the at least one PHR comprises an indicatorindicating whether the at least one PHR comprises a PHR for a primaryserving cell or an indicator indicating whether the PH is based onactual transmission or a reference format.
 3. The method of claim 1,wherein: when one timer is configured in the user equipment, a PHR forthe first base station and a PHR for the second base station aresimultaneously transmitted, and when one timer is configured in each ofthe first base station and the second base station, the PHR for thefirst base station and the PHR for the second base station aretransmitted at different times.
 4. The method of claim 1, wherein: theuser equipment receives downlink signals from one base station of thefirst base station and the second base station at a time and transmitsan uplink signal to only the one corresponding base station at a time,when the PHR for the second base station is triggered and all triggeredPHRs are transmitted, the PHR for a first frequency band is transmitted.5. The method of claim 1, wherein when each of the first base stationand the second base station performs uplink scheduling, the PHR for afirst frequency band is configured only in cells in the first basestation and the PHR for a second frequency band is configured only incells in the second base station.
 6. The method of claim 1, whereindifferent timers are configured in the first base station and the secondbase station.
 7. A method for transmitting a power headroom report (PHR)by a user equipment performing wireless communication based on dualconnectivity, the method comprising: triggering the PHR based on atleast one of a path loss change or a periodic timer; and transmitting atleast one PHR to a first base station and a second base stationaccording to the dual connectivity, wherein the at least one PHRcomprises both a first power headroom (PH) for a first frequency bandthat is a serving frequency of the first base station and a second PHfor a second frequency band that is the serving frequency of the secondbase station, when the user equipment simultaneously receives downlinksignals from the first base station and the second base station andsimultaneously transmits an uplink signal, wherein the user equipmentreceives downlink signals from one base station of the first basestation and the second base station at a time and transmits an uplinksignal to only the one corresponding base station at a time, and whereinwhen the PHR for the second base station is triggered and all triggeredPHRs are transmitted, the PHR for a first frequency band is transmitted.8. The method of claim 7, wherein the transmitting of the at least onePHR comprises transmitting the at least one PHR comprising a first PH tothe first base station and the at least one PHR comprising a second PHto the second base station when an uplink radio connection of the userequipment is configured with the first base station and the second basestation, and the user equipment simultaneously receives downlink signalsbut transmits an uplink signal to only one base station at a time. 9.The method of claim 7, wherein the transmitting of the at least one PHRcomprises transmitting the at least one PHR for a first frequency bandto the second base station when the at least one PHR for the second basestation is triggered based on the user equipment receiving the downlinksignals from one base station of the first base station and the secondbase station at a time and transmitting an uplink signal to only thecorresponding base station at a time.
 10. The method of claim 7, whereinthe at least one PHR comprises an indicator indicating whether the atleast one PHR comprises a PHR for a primary serving cell or an indicatorindicating whether the PH is based on actual transmission or a referenceformat.
 11. The method of claim 7, wherein: when one timer is configuredin the user equipment, a PHR for the first base station and a PHR forthe second base station are simultaneously transmitted, and when onetimer is configured in each of the first base station and the secondbase station, the PHR for the first base station and the PHR for thesecond base station are transmitted at different times.
 12. The methodof claim 7, wherein when each of the first base station and the secondbase station performs uplink scheduling, the PHR for a first frequencyband is configured only in cells in the first base station and the PHRfor a second frequency band is configured only in cells in the secondbase station.
 13. The method of claim 7, wherein different timers areconfigured in the first base station and the second base station.